Inferring Hierarchies of Latent Features in Calcium Imaging Data
Abstract
A key problem in neuroscience and life sciences more generally is that the data generation process is often best thought of as a hierarchy of dynamic systems. One example of this is in-vivo calcium imaging data, where observed calcium transients are driven by a combination of electro-chemical kinetics where hypothesized trajectories around manifolds determining the frequency of these transients. A recent approach using sequential variational auto-encoders demonstrated it was possible to learn the latent dynamic structure of reaching behaviour from spiking data modelled as a Poisson process. Here we extend this approach using a ladder method to infer the spiking events driving calcium transients along with the deeper latent dynamic system. We show strong performance of this approach on a benchmark synthetic dataset against a number of alternatives.
Cite
Text
Prince and Richards. "Inferring Hierarchies of Latent Features in Calcium Imaging Data." NeurIPS 2019 Workshops: Neuro_AI, 2019.Markdown
[Prince and Richards. "Inferring Hierarchies of Latent Features in Calcium Imaging Data." NeurIPS 2019 Workshops: Neuro_AI, 2019.](https://mlanthology.org/neuripsw/2019/prince2019neuripsw-inferring/)BibTeX
@inproceedings{prince2019neuripsw-inferring,
title = {{Inferring Hierarchies of Latent Features in Calcium Imaging Data}},
author = {Prince, Luke Y. and Richards, Blake A.},
booktitle = {NeurIPS 2019 Workshops: Neuro_AI},
year = {2019},
url = {https://mlanthology.org/neuripsw/2019/prince2019neuripsw-inferring/}
}